Salt dependence and thermodynamic interpretation of the thermal denaturation of small DNA restriction fragments

doi:10.1093/nar/9.2.415

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Nucleic Acids Research, 1981, Vol. 9, No. 2 415-436
© 1981

CHEMISTRY

Salt dependence and thermodynamic interpretation of the thermal denaturation of small DNA restriction fragments

Wolfgang Hillen^*, Thomas C. Goodman and Robert D. Wells

Received September 9, 1980.

The influence of cation concentration on the thermal denaturationof DNA restriction fragments from the E. coli lac regulatoryregion and from pVH51, ranging in size from 43- to 880- bp,is described. Upon increasing the ionic strength, the meltingtransitions broaden in a cooperative manner at salt concentrationscharacteristic for the specific fragment. For three fragmentsstudied in detail, the salt concentration dependence at themidpoint varied between 0.03 and 0.19 M Na. Along with the broadening,the melting transitions become more symmetrical. This resultis discussed with respect to the irreversibility of meltingtransitions at low ionic strength. After a cooperative broadening,the shape of the melting curves remains constant up to saltconcentrations of 0.5 M Na⁺. The dT_M/dlog[Na⁺] values for threefragments fall between 15.7 and 16.7. An easily applicable approximationof the van't Hoff equation is used to evaluate the enthalpiesof 13 transitions arising from the denaturation of 43 to 600bp. The results of this analysis are compared to calculationsof the expected enthalpies based on calorimetric measurements.The T_Ms of most transitions were directly related to the basecomposition, but several deviations from the predicted behaviorwere observed. The possible influences of fragment length andsequence on the thermal stability are discussed. The experimentaland mathematical procedure to resolve a thermal denaturationtransition with a width of 0.17 ± 0.01° and its distinctionfrom another preceeding transition only approximately 0.15°away in an 880-bp Hae III fragment from pVH51 is described.This transition is about half as wide as the smallest one reportedto date.

^*Institute für Organische Chemie und Biochemie, TechnischeHochschule Darmstadt Present address: Petersenstr. 22, 61 Darmstadt,FRG.

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